A temperature sensor (1) for gas burner (2) having a thermocouple (11) comprising electric conductors (15) and a connection element (12) to connect to the burner (2) associated with a free end (18) of such thermocouple (11), said connection element (12) being suitable for being inserted inside a seat of the sensor (8) formed inside a wall (4) of the burner (2) and having a first end (26) suitable for being placed at the outer surface (6) of the burner (2), said thermocouple (11) being inserted inside a blind hole (29) of the connection element (12) which opens at a second end (28) of said connection element (12). Said blind hole (29) ends with at least one part (31) convergent towards an end zone (K) of the hole (29), said part (31) getting in contact with the thermocouple (11) inserted inside the connection element, the connection element (12) being made from an iron-chrome-aluminum alloy. An assembly comprising such temperature sensor and a burner is also claimed.

A temperature sensor (1) for gas burner (2) having a thermocouple (11) comprising electric conductors (15) and a connection element (12) to connect to the burner (2) associated with a free end (18) of such thermocouple (11), said connection element (12) being suitable for being inserted inside a seat of the sensor (8) formed inside a wall (4) of the burner (2) and having a first end (26) suitable for being placed at the outer surface (6) of the burner (2), said thermocouple (11) being inserted inside a blind hole (29) of the connection element (12) which opens at a second end (28) of said connection element (12). Said blind hole (29) ends with at least one part (31) convergent towards an end zone (K) of the hole (29), said part (31) getting in contact with the thermocouple (11) inserted inside the connection element, the connection element (12) being made from an iron-chrome-aluminum alloy. An assembly comprising such temperature sensor and a burner is also claimed.

In at least one embodiment, a metal blank is provided including a metal sheet having a surface including at least one pair of channels defined therein. Each channel may have a first portion extending from an edge of the blank and a second portion in an interior of the blank. The second portion may be wider than the first portion. The blank may include at least one pair of thermocouple wires, with one wire being attached to each second portion. An adhesive material may be disposed in each second portion. The wires may be attached by welding and the adhesive material may be a metallic composite adhesive. The disclosed blank may be used to calibrate or otherwise assess a process where the blank is being heated or cooled, such as aluminum hot-stamping.

In at least one embodiment, a metal blank is provided including a metal sheet having a surface including at least one pair of channels defined therein. Each channel may have a first portion extending from an edge of the blank and a second portion in an interior of the blank. The second portion may be wider than the first portion. The blank may include at least one pair of thermocouple wires, with one wire being attached to each second portion. An adhesive material may be disposed in each second portion. The wires may be attached by welding and the adhesive material may be a metallic composite adhesive. The disclosed blank may be used to calibrate or otherwise assess a process where the blank is being heated or cooled, such as aluminum hot-stamping.

The present disclosure is directed to systems, methods and tools that measure ionic concentrations and downhole enthalpy of a flowing geothermal fluid in real-time at high-temperature and pressure. The systems, methods and tools include measuring the concentration of selected naturally occurring ions found in the liquid phase of the geothermal fluid throughout the wellbore using novel electrochemical sensor technologies. The change in liquid-phase ion concentration will be used to calculate the proportion of liquid to steam and allow for accurate enthalpy measurements. The techniques and technologies described here can be applied to any application of electrochemical sensing in extreme environments.

A multi-core thermocouple includes a plurality of wires, an insulation core surrounding the plurality of wires, a sheath surrounding the insulation core, and a plurality of electrical junctions. The plurality of electrical junctions may include a first electrical junction formed between a first wire of the plurality of wires and the sheath at a first axial mid-section of the multi-core thermocouple, the first electrical junction including a first swaged axial mid-section of the sheath and a second electrical junction formed between a second wire of the plurality of wires and the sheath at a second, different axial mid-section of the multi-core thermocouple, the second electrical junction including a second swaged axial mid-section of the sheath.

A multi-core thermocouple includes a plurality of wires, an insulation core surrounding the plurality of wires, a sheath surrounding the insulation core, and a plurality of electrical junctions. The plurality of electrical junctions may include a first electrical junction formed between a first wire of the plurality of wires and the sheath at a first axial mid-section of the multi-core thermocouple, the first electrical junction including a first swaged axial mid-section of the sheath and a second electrical junction formed between a second wire of the plurality of wires and the sheath at a second, different axial mid-section of the multi-core thermocouple, the second electrical junction including a second swaged axial mid-section of the sheath.

A system for determining a temperature of an object includes a three-dimensional (3D) printer configured to successively deposit a first layer of material, a second layer of material, and a third layer of material to form the object. The 3D printer is configured to form a recess in the second layer of material. The material is a metal. The system also includes a temperature sensor configured to be positioned at least partially with the recess and to have the third layer deposited thereon. The temperature sensor is configured to measure a temperature of the first layer of material, the second layer of material, the third layer of material, or a combination thereof.

A sensor system includes a camera including a lens, a casing extending around the lens, at least three heating elements embedded in the casing and arranged circumferentially around the lens, and a computer communicatively coupled to the camera and to the heating elements. The computer is programmed to, upon detecting ice at a location on the lens, select a first subset of the heating elements based on the location of the ice; activate the first subset of the heating elements to a first heating level; determine a second heating level based on an ambient temperature and a lens temperature; and activate a second subset of the heating elements to the second heating level, the second subset including the heating elements not in the first subset.

A sensor system includes a camera including a lens, a casing extending around the lens, at least three heating elements embedded in the casing and arranged circumferentially around the lens, and a computer communicatively coupled to the camera and to the heating elements. The computer is programmed to, upon detecting ice at a location on the lens, select a first subset of the heating elements based on the location of the ice; activate the first subset of the heating elements to a first heating level; determine a second heating level based on an ambient temperature and a lens temperature; and activate a second subset of the heating elements to the second heating level, the second subset including the heating elements not in the first subset.